CsCu2I3 Nanoparticles Incorporated within a Mesoporous Metal–Organic Porphyrin Framework as a Catalyst for One-Pot Click Cycloaddition and Oxidation/Knoevenagel Tandem Reaction

Metal–organic frameworks (MOFs) and metal halide perovskites are currently under much investigation due to their unique properties and applications. Herein, an innovative strategy has been developed combining an iron-porphyrin MOF, PCN-222(Fe), and an in situ-grown CsCu2I3 nontoxic lead-free halide perovskite based on an earth-abundant metal that becomes incorporated within the MOF channels [CsCu2I3@PCN-222(Fe)]. Encapsulation was designed to decrease and control the particle size and increase the stability of CsCu2I3. The hybrid materials were characterized by various techniques including FE-SEM, elemental mapping and line scanning EDX, TEM, PXRD, UV–Vis DRS, BET surface area, XPS, and photoemission measurements. Hybrid CsCu2I3@PCN-222(Fe) materials were examined as heterogeneous multifunctional (photo)catalysts for copper(I)-catalyzed alkyne-azide cycloaddition (CuAAC) and one-pot selective photo-oxidation/Knoevenagel condensation cascade reaction. Interestingly, CsCu2I3@PCN-222(Fe) outperforms not only its individual components CsCu2I3 and PCN-222(Fe) but also other reported (photo)catalysts for these transformations. This is attributed to cooperation and synergistic effects of the PCN-222(Fe) host and CsCu2I3 nanocrystals. To understand the catalytic and photocatalytic mechanisms, control and inhibition experiments, electron paramagnetic resonance (EPR) measurements, and time-resolved phosphorescence were performed, revealing the main role of active species of Cu(I) in the click reaction and the superoxide ion (O2•–) and singlet oxygen (1O2) in the photocatalytic reaction.


INTRODUCTION
Perovskites, as semiconductors, are prospective materials for emerging optoelectronic applications owing to their remarkable physical and chemical features, low manufacturing cost, and adjustable tenability. 1,2 Lead-based perovskites, as the most common perovskites, can be highly efficient for light harvesting; however, they exhibit very low stability and high toxicity, which limit their practical applications. 3,4 Therefore, intensive research has been conducted to develop alternative low toxicity and efficient lead-free perovskites. Among the newly studied lead-free candidates, copper-based perovskites are among the most promising. Particularly, 1D CsCu 2 I 3 exhibits a decent photoresponse and lesser toxicity as well as being constituted by the earth-abundant Cu element. 1,5−8 However, there are some critical points that hamper Cu perovskite preparation, such as the need to add multiple capping agents to limit crystal growth and to stabilize the structure, the use of DMF as a solvent, and/or long crystal growth time. Furthermore, due to their lack of structural stability, the activity of Cu perovskites in (photo)catalysis is largely unexplored, which is important to gain information of their properties as catalysts.
Typically, instable perovskites, such as lead halide perovskites, are stabilized on silica/alumina 9,10 or polymer supports, 11 but frequently, the perovskite is not homogeneously distributed, there are substrate diffusion limitations, and there is metal leaching to the liquid phase. One alternative strategy is to use periodic, well-defined metal−organic frameworks (MOFs) as supports. 12−15 Metal−organic frameworks (MOFs), formed by inorganic nodes and organic connectors interacting by Coulombic and coordination bonds, are highly crystalline and well-defined unique porous frameworks with variable structures and chemical functionalities, tunable pore sizes, high specific surface areas, large internal pore volumes, and low framework densities. 16,17 Because of these intrinsic features, MOFs have been massively studied in various areas. 17−22 Research has shown that hybridization of perovskites with MOFs results in the formation of new multicomponent materials with enhanced stability, higher efficiency, and improved charge transfer and performance compared to the individual components 12−15 or classical supports. 9−11 However, most of reported MOF supports possess micropores (<2 nm), which restricted the mass diffusion and perovskite growth and affected the stability of the MOF structure. 14,15 Therefore, to address these issues, MOFs with ordered mesopores and high porosity, maintaining their stability during and after perovskite loading, are highly demanded but challenging. Particularly, the stabilization of 0D or 1D perovskites provided by encapsulation within MOFs can enable evaluation of the catalytic activity of occluded halide perovskites, something that has remained elusive so far. In addition, the MOF can cooperate with the activity of the occluded perovskite, producing a synergy between the two components in a multifunctional material.
Herein, it is shown that encapsulation of the CsCu 2 I 3 perovskite inside a mesoporous iron-porphyrin PCN-222(Fe) MOF as a host can be achieved by a facile in situ growth to render CsCu 2 I 3 @PCN-222(Fe). By varying the synthetic parameters, CsCu 2 I 3 units uniformly distributed in PCN-222(Fe) and having a strong interaction with the PCN-222(Fe) framework can be prepared. PCN-222(Fe) functions as a support, stabilizing and confining the size and shape of the encapsulated CsCu 2 I 3 nanostructures. Stabilization provided by PCN-222(Fe) has allowed the study of the activity of CsCu 2 I 3 as a heterogeneous catalyst for a three-component CuAAC reaction and one-pot cascade photo-oxidation of benzyl alcohols/Knoevenagel coupling reaction. It was observed that CsCu 2 I 3 @PCN-222(Fe) exhibits high activity for these reactions, outperforming the individual components and other reported catalysts. Remarkably, CsCu 2 I 3 @PCN-222(Fe) was stable and could be easily recovered from the reaction media for reuse with no obvious decay in activity. This stability is remarkable considering the notorious instability characteristic of halide perovskites. Mechanistic studies indicated a synergistic cooperation between CsCu 2 I 3 and PCN-222(Fe). In addition, the host−guest system was further confirmed by using various techniques as described here. The design of multifunctional solid catalysts based on nontoxic elements and the characterization of the synergistic effects derived from the encapsulation of CsCu 2 I 3 , well studied in the field of photovoltaics but not in catalysis, are two of the current research fronts in advanced materials synthesis.

EXPERIMENTAL SECTION
2.1. Materials. Chemical materials such as pyrrole, methyl benzaldehyde-4-carboxylate, propionic acid, benzoic acid, zirconium-(IV) chloride, iron dichloride tetrahydrate, N,N′-diethylformamide (DEF), cesium iodide, copper(I) iodide, acetonitrile, sodium azide, benzyl chloride, phenylacetylene, malononitrile, and benzyl alcohols were synthetically pure and were supplied by Merck. The Fe-TCPP linker was synthesized following a procedure described in the literature. 23 PCN-222(Fe) was synthesized and activated with the HCl-treatment procedure. 23 Synthesis of pure CsCu 2 I 3 perovskite was performed by a modified procedure reported in the literature 7 as mentioned here.

Characterization.
High-quality X-ray diffraction patterns were acquired with Cu K α1 radiation on a Philips, X'Pert XRD diffractometer (Netherlands). FE-SEM imaging, energy dispersive Xray spectroscopy (EDX), and elemental mapping measurements were performed on a scanning electron microscope (TESCAN MIRA3, Czech Republic). Thermogravimetric analysis (TGA) tests were conducted on a TGA/DSC instrument (Mettler Toledo, Germany) under an inert atmosphere. Nitrogen adsorption/desorption isotherms at −196°C were obtained on an ASAP apparatus (Micromeritics, USA). The NMR spectra of the products were recorded on a Bruker Avance DPX-250 NMR (300 MHz for 1 H NMR and 75 MHz for 13 C NMR) in deuterated solvents. The diffuse reflectance spectra were collected by using ultraviolet−visible diffuse reflectance spectroscopy (UV−Vis DRS, Shimadzu Co., Japan). The visible exposure was achieved by 280 power light-emitting diode (LED) lamps (3.2 V, 1 W) in a cylindrical container, 32,000 LUX, including air cooling fans to keep the temperature constant at 31−35°C . The X-ray photoelectron spectra (XPS) were measured on a SPECS spectrometer equipped with a Phoibos 150 9MCD detector using a nonmonochromatic X-ray source (Al) operating at 200 W. The samples were evacuated in the prechamber of the spectrometer at 1 × 10 −9 mbar. The measured intensity ratios of the components were obtained from the area of the corresponding peaks after nonlinear Shirley-type background subtraction and corrected by the transition function of the spectrometer. The work function of the apparatus was calibrated with Ag, Au, and Cu with a value of 4.2440 eV. The EPR spectra were recorded using a Bruker EMX, with the typical settings: frequency, 9; 80 GHz; sweep width, 100 G; time constant, 80 ms; modulation frequency, 100 kHz; modulation width, 0.2 G. Singlet oxygen was studied by time-resolved near-infrared phosphorescence using a home-made setup. Briefly, a pulsed Nd:YAG laser (FTSS355-Q, Crystal Laser) working at 1 kHz repetition rate at 355 nm (third harmonic; 0.5 μJ per pulse) was used for sample excitation. A 1064 nm Rugate notch filter (Edmund Optics) and an uncoated SKG-5 filter (CVI Laser Corporation) were placed at the exit port of the laser to remove any residual component of its fundamental emission in the near-infrared region. The luminescence exiting from the sample was filtered by a 1100 nm long-pass filter (Edmund Optics) and a narrow bandpass filter at 1275 nm (BK-1270-70-B, bk Interferenzoptik). A thermoelectric-cooled near-infrared sensitive photomultiplier tube assembly (H9170-45, Hamamatsu Photonics) was used as a detector. High-resolution TEM (HRTEM) images, scanning TEM (STEM) images, and energy-dispersive X-ray (EDX) spectra were recorded by using a JEOL, JEM 2100F microscope. Steady-state fluorescence measurements were carried out using a Photon Technology International (PTI, Germany) LPS-220B spectrofluorometer equipped with a monochromator in the range of 200−800 nm. The excitation wavelength was 360 nm and emission was recorded from 390 to 700 nm by 1 nm steps with an integration time of 0.1 s, averaging three measurements.

Synthesis of CsCu 2 I 3 .
CuI (1.3 mmol) and CsI (0.65 mmol) were added to a glass vial containing anhydrous acetonitrile (4 mL) before stirring at 60°C for 5 h. Then, the vial was allowed to cool to room temperature and the saturated solution was filtered through a polytetrafluoroethylene (PTFE) (0.45 μm) filter adapted to a syringe. After that, diethyl ether (∼2 mL) was added dropwise to the filtered solution. The white precipitate of CsCu 2 I 3 formed was allowed to grow for 15 min or 3.5 h and collected by centrifugation.
2.5. One-Pot Three-Component Click Reaction. In an unsealed vial, benzyl chloride (0.5 mmol), sodium azide (1 mmol), and phenyl acetylene (1 mmol) were mixed in H 2 O (2 mL) and then the catalyst (10 mg) was added. The resulting mixture was stirred at room temperature and periodically checked by TLC (n-hexane/ethyl acetate (4:1)). After the completion of the reaction, the mixture was diluted by additional H 2 O (4 mL), and the catalyst was removed by centrifugation and washed with ethyl acetate. The organic layer was extracted three times with ethyl acetate, washed with saturated NaHCO 3 , and passed over anhydrous Na 2 SO 4 . Recrystallization from a mixture of ethyl acetate and hexane afforded the pure product.

Tandem Photo-oxidation/Knoevenagel Condensation
Reaction. Into a test tube, benzyl alcohol (0.5 mmol), malononitrile (0.75 mmol), acetonitrile (2−3 mL), and catalyst (15 mg) were mixed and then the mixture was stirred at room temperature under exposure to visible LED illumination and oxygen (an O 2 -filled balloon). The temperature in the illuminated photoreactor was maintained at 33 ± 2°C. After completion of the reaction, the mixture was checked by TLC (n-hexane/ethyl acetate (5:1)), the catalyst was extracted by centrifugation, and the solvent was evaporated under vacuum. The product was finally purified by recrystallization from ethanol/water.   ature employing an antisolvent/inverse solvent infiltration approach using the MOF support (after its synthesis) and CsCu 2 I 3 precursors as shown in Figure 1 (see Section 2 for details). The use of an Fe-porphyrin avoids subsequent partial metalation of free-base porphyrin during the synthesis of halide perovskite while shortening the bandgap of PCN-222 and ensuring a strong O 2 adsorption. Field emission scanning electron microscopy (FE-SEM) images of as-synthesized CsCu 2 I 3 @PCN-222(Fe) (15 min-r.t., 3.5 h-r.t., 15 min-60°C, and 3.5 h-60°C, denoting the time and temperature of the PCN-222 infiltration treatment), individual CsCu 2 I 3 , and pristine PCN-222(Fe) are shown in Figure 2a and Figure S1.

Synthesis and Characterization of CsCu
At a short time (15 min), the images clearly display the selective growth of CsCu 2 I 3 with rod-like morphology along the c axis of hexagonal rod-shaped PCN-222(Fe) crystals. In addition, when the antisolvent was added and aged for 3.5 h, CsCu 2 I 3 nanocrystals were further grown with irregular octahedron-like morphology especially apparent on the surface. It was obvious that the presence of the MOF takes control the growth rate and crystal size of CsCu 2 I 3 , effectively avoiding the agglomeration of the growing crystals (see Figure S1 versus Figure 2a). As shown in the SEM images of Figure 2a and Figure S1, under otherwise identical conditions, smaller CsCu 2 I 3 crystals are obtained in the presence of PCN-222(Fe) owing to its well-defined ordered porous structure, while bigger and enlarged CsCu 2 I 3 crystals or large agglomerations are fabricated in the absence of the MOF. Furthermore, the results showed that the reaction time had more significant influence on the CsCu 2 I 3 particle size and morphology than the reaction temperature.
The porosity of PCN-222(Fe) and CsCu 2 I 3 @PCN-222(Fe) structures with tunable pores was further confirmed by using nonlocal density functional theory models to determine pore size distributions (PSDs). As a result, the pore diameters of PCN-222(Fe) after the in situ growth and immobilization of the CsCu 2 I 3 perovskite decreased as the reaction time and temperature increased, proving further the successful synthetic steps (see Figures S3 and S4 in detail).
The UV−Vis DRS spectra of CsCu 2 I 3 @PCN-222(Fe) samples containing different amounts of CsCu 2 I 3 perovskite recorded at room temperature are shown in Figure S5. Comparison of the UV−Vis DRS spectra of CsCu 2 I 3 @PCN-222(Fe) with those of PCN-222(Fe) shows, as the most remarkable feature, the appearance of an intense peak around 200−400 nm, which can be attributed to the CsCu 2 I 3 perovskite, and notably, the absorbance of CsCu 2 I 3 @PCN-222(Fe) samples covered the entire UV−Vis area. In addition, these UV−Vis DRS spectra indicate that there is a strong interaction between PCN-222(Fe) and the CsCu 2 I 3 guest, leading to changes in the measured spectra of the hybrid material with respect to the sum of the two components. The observed differences in the UV−Vis DRS spectra of the host− guest hybrids might be because of the different loadings of the CsCu 2 I 3 perovskite. Furthermore, the optical bandgaps (E g ) were estimated from the plot of (αhν) 1/2 versus photon energy (hν) (the Tauc equation) obtained from the diffuse reflectance data ( Figure S6). As seen in Figure S6, the E g values of CsCu 2 I 3 @PCN-222(Fe) samples estimated from the intercept of tangents to the Tauc plots were between ∼1.54 and 1.59 eV. Notably, these values are lower than that of the CsCu 2 I 3 perovskite (∼3.78 eV). 1,5,7,8 The presence of the CsCuI 3 perovskite inside PCN-222 is revealed using UV−Vis absorption spectroscopy by the appearance of the characteristic absorption band at 360 nm. Additionally, the composites exhibit different fluorescence spectra than the individual components (Figure 4a,b), indicating that incorporation of CsCu 2 I 3 inside the porphyrin MOF establishes an electronic guest (perovskite)−host (PCN-222) interaction that alters the emission properties. Particularly notable is the position of λ em for the maximum emission intensity that appears to be blue-shifted with respect to 1D CsCu 2 I 3 , which typically appears at λ em > 500 nm. The λ em value of about 450 nm corresponds better to nanoparticles of Cu perovskites due to their small particle size (see below).
The presence of the CsCu 2 I 3 perovskite was also evidenced by X-ray photoelectron spectroscopy (XPS) measurements. Figure S7 displays the XPS spectra of the Cu (2p) region for the whole series of CsCu 2 I 3 @PCN-222(Fe). All samples exhibit strong Cu 2p 1/2 (952.4 eV) and Cu 2p 3/2 (932.4 eV) peaks without any noteworthy Cu(II) satellites at ∼942 and ∼962 eV, demonstrating that the oxidation state corresponds predominantly to Cu(I) in agreement with the formation of the lead-free CsCu 2 I 3 perovskite. 29 Interestingly, these results also indicate that the mesoporous MOF environment successfully prevents the oxidation of Cu + to Cu 2+ even after prolonged thermal treatments. To further confirm the synergistic effects of the PCN-222(Fe) host and CsCu 2 I 3 nanocrystals, XPS peaks of Cs, Cu, and I in CsCu 2 I 3 and CsCu 2 I 3 @PCN-222(Fe) samples were compared ( Figure S8). For CsCu 2 I 3 , the characteristic peak of Cs 3d can be deconvoluted in two components: Cs + at 737.6 eV and Cs−I at 723.69 eV. The Cu 2p spectrum peak is fitted to a Cu−I bond at 931.20 eV. 27,30,31 The I 3d characteristic peaks are attributed to two bonds, Cs−I at 618.11 eV and Cu−I at 619.37 eV. 27,30 It should be noted that the C 1s and O 1s peaks, likely coming from the solvent, are also detected. The notable binding energy shifts are observed in the XP spectra of the composite compared to those of pristine CsCu 2 I 3 (see Figure S8 for details). Also, the elemental signals of the CsCu 2 I 3 @PCN-222(Fe) hybrid show relatively broad peaks as compared to those of CsCu 2 I 3 . Images of the CsCuI 3 perovskite inside the MOF crystals could be obtained by cutting thin nanometric slices of the CsCu 2 I 3 @PCN-222(Fe) material using fast ion bombardment (FIB) and placing these slices in a high-resolution scanning transmission electron microscope. The specimens were thin enough to allow electron transmission imaging. As can be seen in Figure 4c, although large dark dots of about 100 nm corresponding to the CsCuI 3 perovskite were already observed at low magnification, they are most probably due to artifacts formed during the FIB process. At higher magnifications, the STEM images show a very good dispersion of CsCuI 3 dots all around the PCN-222(Fe) matrix (Figure 4d). A considerable number of particles between 2 and 4 nm were clearly visualized in the STEM images, accompanied by larger particles between 5 and 10 nm. It is proposed that the larger particles are formed by agglomeration of the smaller CsCuI 3 particles as a consequence of the FIB manipulation. Dark-field images and EDX analysis confirm that these dots are constituted by Cu, Cs, and I (Figure 4e). Therefore, the HR-STEM study shows a very good dispersion of CsCu 2 I 3 with a considerable fraction of CsCuI 3 particles having a size commensurate with PCN-222 channel dimensions of about 3.2 nm, compatible with the internal incorporation of CsCu 2 I 3 .

Catalytic Properties of PCN-222(Fe)-Encapsulated CsCu 2 I 3 .
Copper(I)-catalyzed intermolecular alkyneazide cycloaddition (CuAAC) reaction, also named as the Sharpless "click" reaction, was reported in 2001 32 and used for the synthesis of triazoles as fine chemicals 33 and for the efficient covalent surface functionalization and covalent attachment under mild conditions. 21 Therefore, the catalytic activity of the CsCu 2 I 3 @PCN-222(Fe) composites was first evaluated for the CuAAC reaction. In this regard, the catalytic performance of the CsCu 2 I 3 @PCN-222(Fe) hybrids was investigated in a new click reaction version, one-pot threecomponent type. The results are summarized in Table 1. Remarkably, CsCu 2 I 3 @PCN-222(Fe) (15 min-r.t., with 0.8 wt % copper and 11.47 wt % zirconium) promoted the reaction at ambient temperature in aqueous media, a naturally abundant and green solvent, and gave the isolated 1,4-diphenyltriazole product with a yield of 98% and a high selectivity of 99.9% after 85 min ( Table 1, entry 1). The reaction is stereoselective with the exclusive formation of the 1,4-isomer without any observation of the 1,5-isomer. 34 Water and water-miscible organic solvent mixtures have been reported as CuAAC reaction media. 33,35−37 Organic reactions in water lacking an organic solvent offer a significant advantage from the environmental point of view, provided that substrates and reagents are soluble in this medium. Since the pore surface is predominantly lined with the hydrophobic organic linkers, the PCN framework has a preference in aqueous solution for adsorption of the organic starting materials into the cavity via "hydrophobic−hydrophobic interactions", 37 thereby increasing the concentration of substrates near the active sites, which increases the catalytic reaction rate and selectivity. When the Cu content increased to 1.93 wt % (CsCu 2 I 3 @PCN-222(Fe)-15 min-60°C, 13.66 wt % zirconium), although the BET surface area and porosity slightly decreased, the activity was almost coincident with that of CsCu 2 I 3 @PCN-222(Fe)-15 min-r.t. (yield of 98% at 80 min) ( Table 1, entry 2). When CsCu 2 I 3 was increased to 11.85 wt % copper (2.94 wt % zirconium) in the case of CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C, the product yield of 98% was achieved at a shorter reaction time of 30 min in comparison with the 15 min samples ( Table  1, entry 3). The activity of CsCu 2 I 3 @PCN-222(Fe) with 13.88 wt % copper (CsCu 2 I 3 @PCN-222(Fe)-3.5 h-r.t.) was almost the same as that of CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C with similar porosity and metal content ( Table 1, entry 4). The data revealed that a balance between porosity and CsCu 2 I 3 loading seems to play an essential role in the performance enhancement of CsCu 2 I 3 @PCN-222(Fe) in this reaction. In other control tests, the catalytic activity of the constructed PCN-222(Fe) and CsCu 2 I 3 was also considered for comparison ( Table 1, entries 5−7). PCN-222(Fe) showed no catalytic activity and gave no product after 1 h (Table 1, entry 5). For CsCu 2 I 3 , the obtained yield was lower than that of the porous CsCu 2 I 3 @PCN-222(Fe)-3.5 h (Table 1, entry 6 vs entries 3 and 4). When physically mixed PCN-222(Fe) and CsCu 2 I 3 were used as a catalyst, the product yield was still lower than that of CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C (Table 1, entry  7).
To show the excellent catalytic performance of our host− guest material, the activity of CsCu 2 I 3 @PCN-222(Fe) was compared with that of previously reported catalysts in this reaction, as given in Table S3. As can be seen in Table S3, the previously reported catalysts such as CuI@UiO-67-IM (IM = imidazolium salt), 36 CuSO 4 ·5H 2 O/sodium ascorbate/β-cyclodextrin, 37 Cu-tetracatechol metallopolymer, 38 CuI 1D polymeric coordination complex, 39 and self-assembled poly-(imidazole-acrylamide)-Cu/sodium ascorbate 40 generally exhibit lower catalytic activity or low selectivity and require higher temperature or longer reaction time in comparison with the use of the CsCu 2 I 3 @PCN-222(Fe) catalyst. Moreover, CsCu 2 I 3 @PCN-222(Fe) was successfully reused and maintained its outstanding performance for the click reaction in terms of both activity and selectivity ( Figure S9). The superior performance of CsCu 2 I 3 @PCN-222(Fe) is attributed to the stabilization by confinement and isolation of the CsCu 2 I 3 active sites within the MOF while still being accessible due to the porosity of the MOF host.
Tandem/cascade reactions, consisting in multistep sequential reactions performed in one pot, are exciting reactions in modern chemistry that can minimize wastes, diminish energy consumption, avoid intermediate workups, and optimize the use of resources. 41 We then were interested in investigating the activity of the synthesized CsCu 2 I 3 @PCN-222(Fe) composites as heterogeneous catalysts for one-pot cascade selective photooxidation of benzyl alcohols/in situ Knoevenagel condensation with malononitrile under visible LED illumination using oxygen (balloon, 1 atm.) as a green oxidant in acetonitrile ( Table 2). There was nearly no product in the absence of either CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C or visible light ( Table 2, entries 1 and 2). In the presence of CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C, the reaction proceeded efficiently upon LED irradiation. The isolated yield of the benzylidenemalononitrile product reached 96% after 15 h with full conversion of benzyl alcohol (>99%) ( Table 2, entry 3). It was also found that CsCu 2 I 3 -loaded PCN-222(Fe) with the lowest amount of copper (CsCu 2 I 3 @PCN-222(Fe)-15 min-60°C) could also promote the reaction and afforded a product yield of 67% within 15 h (Table 2, entry 4). When N 2 was used instead of O 2 , the product yield was suppressed significantly ( Table 2, entry 5), showing the role of O 2 as an oxidant. In a control experiment with pure CsCu 2 I 3 under identical conditions, the yield was very low even after a prolonged time period (Table 2, entry 6). In additional experiments using pristine PCN-222(Fe) MOF and its physical mixture with CsCu 2 I 3 , the product yields were still lower than that of CsCu 2 I 3 @PCN-222(Fe)-3.5 h-60°C (Table 2, entries 7 and 8). These results indicate that the good performance of CsCu 2 I 3 @PCN-222(Fe) in this reaction is ascribed to the existence of the mesoporous MOF host and CsCu 2 I 3 components, establishing a synergistic effect between both of them.
The scope of the CsCu 2 I 3 @PCN-222(Fe) photocatalyst was then surveyed for electron-donating and electron-withdrawing groups, e.g., methyl and chloride, on benzyl alcohols, as shown in Table 3. Under typical conditions, the aromatic alcohols were effectively converted to their corresponding benzylidenemalononitrile products in good yields with high selectivity (>99%) ( Table 3), indicating the potential utility of this photocatalyst. Table S4 also shows the outstanding performance of CsCu 2 I 3 @PCN-222(Fe) compared with the other reported (photo)catalysts 42−46 for this reaction. Several types of photocatalytic/catalytic systems including NH 2 -MIL-101-(Fe), 43 g-C 3 N 4 /FeWO 4 , 42 Au(III)@Cu(II)-MOF, 44 Cu(II)/ amine bifunctional MOF, 45 and Zr-MOF-NH 2 46 have been reported for the production of benzylidenemalononitrile. However, the procedures reported so far have several disadvantages including poor stability, the presence of noble metals, long reaction, the use of oxidant (tert-butyl hydroperoxide or hydrogen peroxide), artificial UV light, and an excess of malononitrile as well as high temperatures and high catalyst loadings, which diminish the interest of the process. On the other hand, in the recent years, due to global warming and the shift in the energy sources, conventional synthetic techniques have moved toward the use of visible light photocatalytic systems, employing LEDs that significantly reduce energy consumption. 47 Notably, the multifunctional CsCu 2 I 3 @PCN-222(Fe) worked well without any additive, at low catalyst loading, and with a low power light source.
Two of the main advantages of using a heterogeneous (photo)catalyst are recyclability and reusability. Therefore, the reuse experiments were performed under the best reaction conditions as presented in Figure S10. The results presented that the hybrid CsCu 2 I 3 @PCN-222(Fe) photocatalyst could be reused for at least four sequential reaction cycles without substantial decay in efficiency ( Figure S10) after its recovery by centrifugation and washing. Atomic absorption spectroscopy (AAS) analysis of the supernatant revealed insignificant copper (0.9% of the total Cu amount in the photocatalyst) and iron leaching (0.4%). The comparison of fresh and reused PXRD profiles (Figures S11) and SEM images ( Figure S12 versus Figure 2a) revealed that CsCu 2 I 3 @PCN-222(Fe) has retained its crystallinity and particle morphology after the cascade reaction. In addition, EDX elemental analysis of the photocatalyst indicated that the metal contents do not change significantly after its reuse ( Figures S13 and S14 versus Tables S1 and S2). The recovered catalyst was further assessed by using TGA, which shows the same profile as that of the fresh one ( Figure S15). All the available data indicate that CsCu 2 I 3 @ PCN-222(Fe) is an active, stable, and reusable multifunctional catalyst. These stability data are remarkable considering the small size of the particles and the instability of iodide perovskites.
The work showed that the integration of a semiconductorlike porphyrinic MOF, PCN-222(Fe), with perovskite CsCu 2 I 3  nanocrystals results in synergistic effects derived from confinement and affords an optimized and efficient catalytic system for the tandem reaction.

Mechanistic Studies.
A plausible mechanism for the three-component azide-alkyne 1,3-dipolar cycloaddition reaction toward the regioselective synthesis of 1,4-diphenyl-1,2,3triazole is depicted in Scheme 1. CsCu 2 I 3 @PCN-222(Fe) including well-dispersed Cu(I) species 33 composing CsCu 2 I 3 ( Figures S7 and S8) can act as a heterogeneous multifunctional catalyst promoting the various sequential steps: the first step is the in situ generation of 1,4-phenyl azide via aromatic nucleophilic substitution reaction between sodium azide and benzyl bromide, the second step is the deprotonation of the terminal hydrogen of phenyl acetylene, and the third step is the [3 + 2] cycloaddition reaction between the deprotonated phenyl acetylene and the in situ-formed azide to afford the desired 1,4-isomer product as shown in Scheme 1. It should be noted that the mesoporous MOF host allows the accessibility of these reactants to the Cu(I) sites and prompts the reactions within the cavities.
To gain key insights into the mechanistic scenarios of the one-pot cascade transformation over CsCu 2 I 3 @PCN-222(Fe), additional control experiments were carried out (see Scheme S1 and also the experiments given in Table 2). In the cascade reaction between benzyl alcohol and malononitrile, benzaldehyde appears as an intermediate. Photocatalytic oxidation of benzyl alcohol to benzaldehyde takes place without overoxidation to benzoic acid, which was barely detected during the course of the reaction (Scheme S1a). In another control test, under the same condition, when benzyl alcohol was replaced by benzaldehyde, the desired benzylidenemalononitrile was produced quantitatively after a short reaction time of ∼30 min even in the dark (Scheme S1b,c). These tests confirmed that the condensation reaction between benzaldehyde and malononitrile is easier and faster (Scheme S1) than the photo-oxidation process, which is the rate-determining step in the cascade reaction. The controls reveal that the host− guest hybrid material serves as a multifunctional (photo)catalyst including also both Lewis acidic sites such as Fe 3+ , Zr +4 , Cu + , and Cs + (see Scheme S1 for additional experiments and Figure S16) and redox-active sites of PCN-222(Fe) and lead-free CsCu 2 I 3 perovskite as the light absorber. Both components operate synergistically.
To further identify the prevalent reactive oxygen species (ROS) in the present system promoting the photo-oxidation step, inhibition experiments by adding quenchers such as 1,4benzoquinone (superoxide radical anion (O 2 •− ) scavenger), sodium azide (singlet oxygen ( 1 O 2 ) scavenger), and methanol (hole (h + ) scavenger) to the reaction mixture were performed ( Figure S17). The quenching study is compatible with the in situ formation of O 2 •− and 1 O 2 (main species) as well as h + (minor species) during the photocatalytic process, as assessed by the decrease in product yield. Electron paramagnetic resonance (EPR) measurements were then performed to quantify the in situ-generated O 2 •− and 1 O 2 as the ROS in this system ( Figure 5). Using 2,2,6,6-tetramethylpiperidine (TEMP) as a specific 1 O 2 trapping agent, a strong triplet signal of an intensity ratio of 1:1:1, corresponding to TEMPO, was detected after light irradiation, which confirmed the formation of 1 O 2 (Figure 5a). To confirm O 2 •− generation, 5,5-dimethyl-1-pyrroline N-oxide (DMPO), as a specific O 2 •− trapping agent, was used, which generated multiline EPR signals after light irradiation (Figure 5b), corresponding to DMPO-O 2 •− and nitroxide-related radicals 48 resulted from 1 O 2 /O 2 •− -driven DMPO decomposition. It should be noted that no radical and no EPR signal were detected under dark conditions. Furthermore, the lifetime of the singlet oxygen formed within the porous CsCu 2 I 3 @PCN-222(Fe) photocatalyst was measured by the time-resolved phosphorescence technique. 49 The method permits one to quantify directly the generation of 1 O 2 by detecting its characteristic phosphorescence in the nearinfrared (NIR) region (Figure 5c,d). Upon single-pulse laser excitation at 355 nm, the time-resolved NIR phosphorescence showed a 1 O 2 lifetime of up to 100 ns for the CsCu 2 I 3 @PCN-222(Fe) photocatalyst.
The •− and 1 O 2 ) to produce the corresponding aldehyde product (II) and H 2 O 2 by-product. The observed selectivity of the P@MOF is likely regulated by the micro/meso-hierarchical hydrophobic structure, which allows the free diffusion of substrates/ products and prevents over-oxidation by the same species of the hybrid catalyst. Next, the P@MOF including the Lewis acid sites (such as Fe 3+ , Zr +4 , Cu + , and Cs + ) activates the in situ-produced aldehyde and malononitrile (III) for a nucleophilic addition of the Knoevenagel coupling reaction toward the formation of the final product (IV). Subsequently, the (photo)catalyst is ready for another round of tandem reaction.

CONCLUSIONS
Briefly, tetrametallic multifunctional porous CsCu 2 I 3 @PCN-222(Fe) hybrid materials have been creatively planned and fabricated by post-synthetic modification of iron-porphyrin PCN-222(Fe) with the earth-abundant and lead-free CsCu 2 I 3 perovskite via the antisolvent protocol using the MOF and the same amount of CsCu 2 I 3 precursors (CuI and CsI). Characterization of CsCu 2 I 3 @PCN-222(Fe) rods shows unique structural and functional properties arising from the collective active sites of the CsCu 2 I 3 nanoparticles incorporated inside the MOF pores, providing stabilization of the iodide perovskite. These properties have allowed the use of CsCu 2 I 3 @PCN-222(Fe) as a heterogeneous catalyst, revealing a remarkable catalytic activity for the three-component click reaction and one-pot selective photo-oxidation/Knoevenagel domino reaction with oxygen (1 atm) under visible light. The CsCu 2 I 3 @PCN-222(Fe) composite performs better than benchmark catalysts for these two processes. The activity appears to be a balance between porosity and CsCu 2 I 3 loading. Outstandingly, CsCu 2 I 3 @PCN-222(Fe) was stable under reaction conditions and can be reused several times. Considering the diversity of halide perovskites, our results open the way to exploit the potential in the catalysis of these materials upon encapsulation inside MOFs.